KR20060050183A - High voltage bulk circuit breaker - Google Patents

Abstract

The present invention is to provide a high-voltage large-capacity circuit breaker capable of miniaturization and high-voltage large-capacity by increasing the rated current in accordance with the demand of the recent power system.

To this end, first, the current to be blocked by opening the third opening and closing part 3 causes a series connection part of the first opening and closing part 1 and the second opening and closing part 2 to flow, and then the vacuum blocking part constituting the first opening and closing part 1. The current is cut off by a predetermined distance between the electrodes, and at the same time, it withstands the excessive vibration voltage appearing between the poles, and then, for example, between the electrodes of the first opening / closing part 1 becomes a predetermined opening distance. After the maximum arc time, the second opening and closing portion 2 is opened to withstand the more severe impulse voltage at the second opening and closing portion 2.

Description

HIGH VOLTAGE CAPACITY CIRCUIT {HIGH VOLTAGE BULK CIRCUIT BREAKER}

1 is a disconnection diagram showing a high voltage large capacity circuit breaker according to an embodiment of the present invention;

2 is a disconnection diagram showing a high voltage large capacity circuit breaker according to another embodiment of the present invention;

3 is a stroke characteristic diagram of each opening and closing part in the high voltage large capacity circuit breaker shown in FIG. 1;

4 is a breakdown voltage characteristic diagram of each switch unit in the high voltage large capacity circuit breaker shown in FIG. 1;

5 is a cross-sectional view showing a concrete configuration example of the high voltage large capacity circuit breaker shown in FIG. 1;

FIG. 6 is a plan view showing a first delay mechanism in the high voltage high capacity circuit breaker shown in FIG. 5;

FIG. 7 is a plan view showing an operation middle state of the first delay mechanism shown in FIG. 6;

8 is a plan view showing an operation completion state of the first delay mechanism shown in FIG. 6;

9 is a cross-sectional view showing a specific configuration example of a high voltage large capacity circuit breaker according to another embodiment of the present invention;

10 is a cross-sectional view showing a specific configuration example of a high voltage large capacity circuit breaker according to still another embodiment of the present invention;

11 is a cross-sectional view showing a specific configuration example of a high voltage large capacity circuit breaker according to still another embodiment of the present invention;

12 is a disconnection connection diagram showing a high voltage large capacity circuit breaker according to still another embodiment of the present invention.

※ Explanation of code for main part of drawing

1: first opening and closing portion 2: second opening and closing portion

3: third opening and closing portion 11: fixed contactor

12: movable contact 15: puffer seal

16: fixed main contactor 17: vacuum valve

18: fixed electrode 19: movable electrode

20: movable main contactor 21: insulated rod

22: bellows 23: holder

25: engaging portion 26: first delay mechanism

29: second delay mechanism

The present invention relates to a high voltage large capacity circuit breaker using a vacuum interrupter.

Currently, the high-voltage large-capacity circuit breaker of the power system is monopolized by the SF6 gas circuit breaker. Vacuum breakers are also widely used in other applications. However, due to the blocking characteristics, the opening distance between electrodes in the vacuum cannot be increased so that the breakdown voltage against lightning impulses after the current interruption cannot be increased. Since the electrode which conducts electricity in a steady state is provided in contact with a vacuum, and it comes in contact contact, heat_generation | fever by energization heats only by heat conduction, and it is known for small and medium-sized rated current because a small electricity supply amount.

As a circuit breaker composed of a vacuum circuit breaker, the arc generator switch and the vacuum circuit breaker are electrically connected in series, and the circuit breaker which forms the main circuit in parallel with them is connected to open the circuit breaker. It is known to open an arc to generate an arc, to attenuate a fault current containing a direct current component by this arc electrical resistance, and to open a vacuum circuit breaker thereafter (Patent Document 1).

[Patent Document 1]

Japanese Patent Application Laid-Open No. 2001-195960

However, the surrounding environment of the SF6 gas circuit breaker has been greatly changed recently. For example, SF6 gas has a warming coefficient of 24000 times that of CO2 and is designated as a warming gas of the COP3 Kyoto Protocol, which may limit its use in the future. In addition, according to the new ANSI standard, the voltage rise severity on the power supply side is 1.73 times in the system condition, and in order to cope with the gas breaker, it is necessary to replace the circuit breaker of two ratings, for example, a 63 kA breaker if it has been a 40 kA breaker. Or the addition of a large capacity capacitor of several tens of nF. In addition, there is a tendency that the loss of the line progresses, or the overseas DC current attenuation time constant increases during a system accident due to the long distance of the transmission line, and the current standard value is 45 ms, but there is an example of 385 ms overseas. Normally, the arc time width required for the interruption should be about 0.5 cycles, but 1.0 cycles are required at 385 ms. In response to such a demand, a current gas circuit breaker is difficult to respond to.

It is an object of the present invention to provide a high-voltage large-capacity circuit breaker capable of miniaturization and high-voltage large-capacity by increasing the rated current according to the demand of the recent power system.

The present invention provides a high-voltage large-capacity circuit breaker having a first opening and closing portion using a vacuum interrupter and a second opening and closing portion electrically connected in series with the first opening and closing portion to achieve the above object. It is characterized in that the opening and closing portion withstands the excessive vibration voltage after the current interruption, and after that, the second opening and closing portion is opened so that the second opening and closing portion withstands the impulse voltage and completes the blocking.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described based on drawing.

1 is a disconnected connection diagram of a high voltage large capacity circuit breaker according to an embodiment of the present invention.

It has a high voltage with a 1st switch part 1, the 2nd switch part 2 electrically connected in series with this 1st switch part 1, and the 3rd switch part 3 electrically connected with the 1st switch part 1 in parallel. A large capacity breaker is configured. The 1st opening / closing part 1 is comprised with the vacuum interruption | blocking part excellent in the current interruption | blocking characteristic which isolates between electrodes in vacuum and performs a current interruption. On the other hand, the second opening / closing section 2 is configured to open the contacts between the contacts in an insulating medium other than vacuum, for example, an insulating gas. The second opening / closing section 2 opens the contacts between the contacts after the current is interrupted by the first opening / closing section 1 to provide high breakdown voltage characteristics. At the same time, it is constituted by a gas opening / closing part which can obtain a large opening distance relatively easily as compared with the vacuum interrupting part. The third opening and closing portion 3 energizes most of the rated current in the closing state to form a main current path, and is opened prior to the opening of the first opening and closing portion 1 and the second opening and closing portion 2.

The vacuum interrupter constituting the first opening / closing part 1 may use a configuration commonly known as a vacuum interrupter. For example, an electromagnetic driving force generated by a groove formed in the electrode by generating an arc between electrodes opened at a predetermined distance, and the like. By using this, the arc is rotated at the opposite side between the electrodes to meet the current zero to cut off the current. The first opening / closing unit 1 has a current blocking capability of blocking all accident currents generated in the system, and after the arc is extinguished between electrodes opened at a predetermined distance, a transient vibration voltage appears between the electrodes. It is configured with blocking performance. On the other hand, since the gas opening / closing portion constituting the second opening / closing portion 2 can take a relatively large opening distance without limiting the opening distance between electrodes as in the above-mentioned vacuum interrupting portion, there is a transient vibration within the rated breaking time as the circuit breaker. It is configured to withstand impulse voltages such as multiple lightning impulses that are more severe than voltage.

In the closed state, the first opening and closing part 1, the second opening and closing part 2, and the third opening and closing part 3 are all closed, and the rated current of the main circuit is the second opening and closing part 2 and the third opening and closing part 3. It's flowing. The blocking operation is performed by a manipulator, not shown, which receives a trip signal, and first, the current to be blocked is opened by opening the third opening and closing part 3 so that the series connection part of the first opening and closing part 1 and the second opening and closing part 2 flows. Subsequently, after the current is cut off by opening the first opening and closing portion 1, the second opening and closing portion 2 is opened at the predetermined timing described later. On the other hand, at the time of inputting, the second opening / closing part 2 is closed first, then the first opening / closing part 1 is closed, and finally the third opening / closing part 3 is closed.

In more detail, this breaking operation is given, so that the trip signal is given, and as shown in the stroke characteristic 4 shown in Fig. 3, the third opening and closing portion 3 is first opened at time t1, and the breaking current is immediately connected with the first opening and closing portion 1. The second opening and closing part 2 flows. Subsequently, when the inter-pole dielectric breakdown voltage of the 3rd opening / closing part 3 exceeds the inter-pole dielectric breakdown voltage of the 1st opening-and-closing part 1, the 1st opening-and-closing part 1 opens at time t2, as shown to the stroke characteristic (5). Because it is a vacuum cut-off part, it reaches the opening position with a short stroke, and the arc generated between the electrodes receives electromagnetic driving force and rotates at the opposite part of the electrode to meet the current zero and cut off the current. Transient vibration voltage is applied, but the breakdown is completed by withstanding it. Thereafter, as shown in the stroke characteristic 6, the second opening and closing portion 2 is opened via an electrical or mechanical delay mechanism based on the same trip signal at time t3, and the second opening and closing portion 2 is high as described above. Since insulation resistance is obtained, insulation maintenance with respect to an impulse voltage, such as multiple lightning impulses, which is severer than a transient vibration voltage is performed.

After the 1st opening / closing part 1 opens, the timing which opens the 2nd opening / closing part 2 can be set in various ways. For example, after opening the third opening and closing portion 3, the first opening and closing portion 1 is opened to withstand the excessive vibration voltage at the first opening and closing portion 1, and then the second opening and closing portion 2 is opened to open the second opening and closing portion ( It can withstand the impulse voltage in 2). In order to realize this, the third opening / closing part 3 is opened based on the trip signal, and thereafter, the operating force is transmitted in a delay with respect to the trip signal to open the first opening / closing part 1 and the excessive vibration voltage is generated in the first opening / closing part 1. The second switch may be configured to withstand the impulse voltage by passing the operation force by delaying again with respect to the same trip signal, and then opening the second switch 2.

Moreover, the timing which opens the 2nd opening-and-closing part 2 opens the 1st opening-and-closing part 1 after opening the 3rd opening-and-closing part 3 based on a trip signal, and between the electrodes of this 1st opening-and-closing part 1 is predetermined. The second opening / closing part 2 may be opened based on the same trip signal after the maximum arc time after the opening distance is. More specifically, the timing of opening the second opening / closing part 2 is opened at least 0.6 cycles after the first opening / closing part 1, which is the vacuum blocking part, opens and the electrode reaches a predetermined opening distance in the above-described blocking operation. The maximum arc time of the first opening / closing part 1, which is the vacuum interrupter, is 0.6 cycles, i. As can be seen from these descriptions, a circuit breaker is constituted by a series connection of the first opening and closing portion 1 and the second opening and closing portion 2, and the second opening and closing portion 2 is a circuit breaker system after a rated breaking time. It is not the same as the disconnector, which opens the main circuit to separate it from.

The insulation breakdown voltage characteristics of the opening and closing portions 1 to 3 during this breaking operation are as shown in FIG. As shown in the insulation breakdown voltage characteristic curve 7, the third opening and closing part 3 starts to open at time t1 and gradually improves the breakdown voltage. When the inter-pole dielectric breakdown voltage of the third open-close portion 3 exceeds the inter-pole dielectric breakdown voltage of the first open-close portion 1, the first opening-closing part 1 starts to open at time t2 as shown in the insulation breakdown voltage characteristic curve 8. At the outset, a relatively short opening distance between electrodes is reached to perform current interruption. Although the dielectric breakdown voltage is shown at that time, since the 1st opening-and-closing part 1 consists of a vacuum interruption part, since the opening distance between electrodes is small, sufficient breakdown voltage cannot be acquired with respect to severe overvoltages, such as an impulse voltage. Therefore, at the time t3 within the rated breaking time as the breaker, the second opening and closing part 2 starts to open, but since the second opening and closing part 2 is composed of a gas opening and closing part, as shown in the insulation breakdown voltage characteristic curve 9, It can start to open at t3 and take a large stroke on a relatively freeway, and rapidly improve the insulation breakdown voltage as compared to each other opening and closing part to operate to the position with the highest insulation breakdown voltage. Therefore, a high breakdown voltage breaker is realized by the combination with the second opening / closing section 2 while using a vacuum breaker having a low breakdown voltage as the whole high voltage breaker.

In the vacuum circuit breaker using the vacuum interrupter, the vacuum breaker has a pair of openable electrodes in the vacuum chamber, and both of the electrodes are in contact with each other, so that the heat generated by the energization in the vacuum interrupter is radiated out of the vacuum valve only by the heat conduction. In general, since a sufficient cooling effect cannot be expected, the current carrying capacity is suppressed small. However, in the high-voltage large-capacity circuit breaker described above, the rated current of the main circuit mainly flows not the first opening / closing part 1 but the third opening / closing part 3 electrically connected in parallel with the first opening / closing part 1, so that the vacuum interrupting part It is possible to increase the energizing current of the main circuit while suppressing heat generation in the first opening / closing part 1 configured by the above. In addition, after the current interruption is completed in response to the transient vibration voltage applied between the poles, the second opening / closing part 2 is opened based on the trip signal already given. Since the second opening / closing part 2 can be configured to open between contactors in an insulating medium different from the vacuum cut-off part, for example, an insulating gas, a large dielectric strength of the insulating gas is used, and the vacuum cut-off part On the contrary, a large breakdown voltage can be obtained by sufficiently increasing the opening distance between the contacts, and good insulation is maintained against multiple lightning impulses.

It is sectional drawing which shows the specific structure of the high voltage high capacity circuit breaker which concerns on one Embodiment of this invention.

Insulated gas is enclosed in the sealed container which is not shown in figure, and the one terminal 10 is supported and fixed in the state electrically insulated from this sealed container. The fixed contact 11 of the gas opening / closing part is fixed to the terminal 10, and the movable contact 12 facing the fixed contact 11 is fixed to the cylinder 14. The cylinder 14 is guided by the upper end plate of the vacuum valve 17 and the fixed main contact portion 16 fixed thereto, thereby forming a simple puffer chamber 15. By operating the movable contact 12 and the cylinder 14 downward, the insulating gas in the puffer chamber 15 rises in pressure and is guided by the insulating cylinder 13 between the fixed contact 11 and the movable contact 12. Flushed. The lower end plate 31 of the vacuum valve 17 is fixed as a fixing member together with the upper end plate by an insulating container constituting the vacuum valve 17, and is attached to the lower end plate 31 of the vacuum valve 17. The movable main contactor 20 is slidably mounted with respect to the actuator, and is connected to the manipulator via the insulating rod 30. The 1st opening-and-closing part 1 shown in FIG. 1 is comprised by the vacuum valve 17 etc., and the 2nd opening-and-closing part 2 shown in FIG. 1 is comprised and fixed by the fixed contact 11 and the movable contact 12 etc. The 3rd opening-closing part 3 shown in FIG. 1 is comprised by the main contactor 16, the movable main contactor 20, etc. As shown in FIG.

The vacuum valve 17 which comprises the 1st opening-and-closing part 1 shown in FIG. 1 has the pair of openable fixed electrode 18 and the movable electrode 19, and it operates while maintaining a vacuum by the bellows 22. As shown in FIG. In the configuration that allows the opening operation of the electrode 19, if the movable electrode 19 is opened so that a constant opening distance is maintained between the fixed electrode 18, an arc occurs between both electrodes 18 and 19. At the same time, the current is blocked by the current zero while rotating the arc at the opposing part between the electrodes 18 and 19 under the electromagnetic driving force of the electrode structure, and the transient vibration voltage appears between the poles immediately after the current is cut off. The current interruption is completed by withstand voltage. Such a structure is a structure known as a vacuum circuit breaker. The holder 23 connected to the movable electrode 19 is drawn out from the lower part of the movable main contactor 20, and the movable main contactor 20 and the other side not shown by the current collector 24 provided in the derivation portion. It is connected to the terminal.

This 1st opening-closing part 1 is operated by the manipulator via the 1st delay mechanism 26 mentioned later in detail. When the first delay mechanism 26 maintains a constant opening distance between at least the movable electrode 19 and the fixed electrode 18, the fixed main contactor 16 of the previously opened third opening / closing portion 3 is opened. And a delay mechanism for opening the first opening / closing portion 1 by delaying the opening and closing of the third opening and closing portion 3 by the trip signal so that the internal pressure higher than the internal pressure between the movable main contactors 20 is maintained.

This 1st delay mechanism 26 is comprised so that operation may be started by the engaging part 25 formed in the opposing part in the insulating rod 30. As shown in FIG. As shown in FIG. 6, this 1st delay mechanism 26 has the 1st lever 32 which connected one end to the holder 23 of the vacuum valve 17, and the other end of this 1st lever 32. As shown in FIG. It is comprised with the 2nd lever 33 which connected one end with a clearance, and the injection | pouring spring 34 which gives a counterclockwise rotational force to the other end of this 2nd lever 33. As shown in FIG. In the closed state, the closing spring 34 gives the second lever 33 a counterclockwise rotational force, and the first lever 32 gives a clockwise rotational force to move the movable electrode 19 to the fixed electrode ( It is pressed against 18).

One end of the insulating rod 21 is connected to the cylinder 14, and one end of the lever 27 is connected to the other end of the insulating rod 21. The other end of the lever 27 is connected to one end of the lever 29 via a link 28 and via a second delay mechanism 51 which is a connecting portion having a margin, and the other end of the lever 29. Is connected to the insulating rod 30. The second delay mechanism 51 maintains a constant opening distance between the movable electrode 19 and the fixed electrode 18 of the first opening / closing part 1 by a trip signal, and then, for example, after the second cycle, for example, after the 0.6 cycle, It is a delay mechanism for opening and closing the opening / closing part 2. Accordingly, when the insulating rod 30 is driven downward by the manipulator (not shown), the movable main contactor 20 is first opened from the fixed main contactor 16, and then the vacuum valve is passed through the first delay mechanism 26. (17) is opened, and then the movable contact 12 is opened from the fixed contact 11 by driving the cylinder 14 and the movable contact 12 via the second delay mechanism 51 or the like.

Next, the blocking operation of the high voltage high capacity circuit breaker will be described.

In the closed state shown in the drawing, the rated current is one terminal 10 → fixed contactor 11 → movable contactor 12 → cylinder 14 → movable main contactor 6 → fixed main contactor 20 → current collector ( 24) Flowing in the circuit to the other terminal. When a trip signal is given to a manipulator (not shown) to drive the insulating rod 30 downward, the movable main contactor 20 is first opened from the fixed main contactor 16. Then, the conduction current is generated from one terminal 10 → fixed contactor 11 → movable contactor 12 → cylinder 14 → movable main contactor 6 → fixed electrode 18 → movable electrode 19 The electrons 24 flow in the circuit to the other terminal.

Next, when the insulating rod 30 is driven downward by a predetermined distance to obtain a predetermined dielectric breakdown voltage between the movable main contactor 20 and the fixed main contactor 16, the engaging portion 25 causes the first delay mechanism ( 26) is activated. As shown in FIG. 6, the first retardation mechanism gives a counterclockwise rotational force to the second lever 33 by the closing spring 34, and a clockwise rotational force to the first lever 32 to provide the movable electrode. (19) is pressed against the fixed electrode 18 to maintain the state shown. However, as shown in FIG. 7, when the engaging portion 25 contacts the other end of the second lever 33 and resists the closing spring 34 to rotate the second lever 33 clockwise, it has a margin. By connecting, the first lever 32 is rotated counterclockwise. Thereafter, the second lever 33 is held by the opposing spring 34 by the opposing surface of the insulating rod 30 past the engaging portion 25, as shown in FIG.

In this way, the movable electrode 19 is driven in the blocking direction so that a constant opening distance is maintained between the fixed electrode 18 and an arc is generated between both electrodes 18 and 19, Under the electromagnetic driving force, the current is cut off while the arc is rotated at the opposing part between the electrodes 18 and 19 to meet the current zero, and a transient vibration voltage is applied between the poles immediately after the current cut, but withstand voltage Is complete. After the maximum arc time, i.e., 0.6 cycles, between the movable electrode 19 and the fixed electrode 18 becomes a constant opening distance, this time, the second delay mechanism 51 is operated to activate the movable contactor 12 from the fixed contact 11. ) Is cleared.

In this operation timing, when the movable electrode 19 and the fixed electrode 18 shown in FIG. 5 have a constant opening distance, the lever 29 rotates clockwise by the operation in the blocking direction of the insulating rod 30. This can be achieved by setting the margin between the link 28 by the second delay mechanism 51 to be absorbed. When the allowance of the second retardation mechanism 51 is absorbed, the lever 29 rotates the lever 27 counterclockwise through the link 28, and moves the cylinder 14 and the movable rod through the insulating rod 21. The contactor 12 is driven downward to block the gas opening and closing part. An insulating gas having a high dielectric strength is enclosed in the sealed container of the gas opening and closing part, and by setting the lever ratio of the lever 27 or the like appropriately, a large opening distance can be ensured, even when a multiple lightning impulse voltage is applied. Shut off the operation with enough pressure.

The high-voltage large-capacity circuit breaker having such a configuration is provided by the third main opening and closing portion 3 by the fixed main contactor 16 and the movable main contactor 20, while using a vacuum interruption part that is weak against the impulse withstand voltage such as current carrying performance or multiple lightning strikes. Most of the rated current flows and the rated current can be increased by preventing heat generation at the vacuum interrupter. In addition, since the second opening / closing portion 2 is formed of the fixed contactor 11 and the movable contactor 12 to be opened in the insulating gas, the impulse withstand voltage is increased by using the insulating gas here or by increasing the opening distance as compared with the vacuum interrupter. Can be.

In addition, according to such a high-voltage large-capacity circuit breaker, the second opening / closing part 2 is configured as an opening / closing part in an insulating medium other than vacuum, so that the open stroke is larger than that of the vacuum interrupting part, and the breakdown voltage performance is improved by utilizing the insulating characteristics of the insulating gas. I can raise it and can withstand a lightning impulse. As the insulating gas enclosed in the hermetically sealed container, the second opening / closing part 2 may use at least one of SF 6 gas, dry air, CO 2 gas, N 2 gas, CF 3 I, a plurality of mixed gases, insulating oil, or the like. In any case, since it is not necessary to use a gas having excellent breaking performance in order to perform the current interruption in the vacuum interrupter, reducing the amount of SF6 gas used or configuring the second opening / closing part 2 without using the SF6 gas at all will result in environmental harmony. High voltage large capacity circuit breaker.

In general, warming is not a constant rise in temperature, but rather a constant climate change. Therefore, the -50 ℃ specification, which is already required in the future, is expected to be further expanded. However, by using a gas density that satisfies these conditions without using SF6 gas at all, a high-voltage large-capacity circuit breaker corresponding to this is obtained. Lose. In addition, including the environmental problems, the manipulator does not use oil from the hydraulic manipulator, and the movement to the spring manipulator with a simple structure is a big flow. However, although it is difficult to configure 63 kA as a spring operator with a puffer-type gas circuit breaker, the high voltage large-capacity circuit breaker is obtained by using a simple spring operator by configuring as described above.

In addition, in the high voltage large-capacity circuit breaker shown in FIG. 5, the second opening / closing part 2 having the puffer chamber 15 may be omitted. However, the puffer chamber 15 may be omitted and is much smaller and simpler than the buffer type gas circuit breaker. It can also be set as the buffer chamber 15, and it can be set as a small high voltage large capacity circuit breaker as a whole. In addition, the control switch is expected to be spread in the future to improve the power quality, such as switching surge and inrush current suppression. However, the puff-type gas circuit breaker has a long stroke and a long input time. These control opening and closing can be performed relatively easily.

2 is a circuit diagram showing a high voltage large capacity circuit breaker according to another embodiment of the present invention.

The high-voltage large-capacity circuit breaker in this embodiment electrically connects the first opening / closing part 1 which is a vacuum interruption part and the 2nd opening / closing part 2 comprised in gas in series, and the 1st opening / closing part 1 and the 2nd opening / closing part ( The third opening and closing part 3 which forms a main current path electrically in parallel with 2) is connected.

In the above-described embodiment, the first opening / closing part 1 is opened after the third opening / closing part 3, and after the maximum arc time is reached based on the trip signal after the predetermined opening distance is reached between the electrodes of the first opening / closing part 1. The second opening / closing part 2 is opened, or the first opening / closing part 1 is opened continuously to the third opening-and-closing part 3 based on the trip signal, and thereafter, the second opening-and-closing part 2 is opened within the rated breaking time based on the same trip signal. Although the 2 opening / closing part 2 was opened, it is not limited to this. That is, after opening the 1st opening / closing part 1 continuously to the 3rd opening / closing part 3, after constructing the 2nd opening / closing part 2 to fully open state within 0.3 second, or opening the 1st opening / closing part 1, The second opening / closing part 2 may be configured to be in a fully open state from 8.3 ms to 10 ms.

When the second opening and closing portion 2 is configured to open at such timing, the first opening and closing portion 1, which is generally constituted by the vacuum blocking portion, is subjected to current blocking in two to three cycles to open the first opening and closing portion 1, Since the second opening / closing part 2 is fully opened within 0.3 seconds, a high-voltage large-capacity circuit breaker requires a high-speed reintroduction to ensure system stability, and a re-introduction operation must be started after 0.3 seconds after the shutdown. You can satisfy this task. The circuit breaker becomes the maximum value at 0.5 cycle after breaking the fault current, that is, 8.3 ms at 60 Hz and 10 ms at 50 Hz. At this time, the reverse polarized lightning impulse is applied, resulting in the highest insulation duty. Since the second opening / closing portion 2 is completely opened after 8.3 ms to 10 ms after the opening portion 1 is opened, this severe insulation duty can be easily satisfied.

9 is a schematic front view showing a specific configuration example of the high voltage high capacity circuit breaker described above.

An insulating gas is sealed in the sealed container 44, and one terminal 10 is supported and fixed in the state in which it is electrically insulated from the sealed container 44 by the insulator 35. The terminal 10 is fixed with a fixed contactor 11 of the gas opening and closing portion through a high conductor 43, and the movable contactor 12 facing the fixed contactor 11 is always in contact with the current collector 45. It is connected to the insulating rod 21 so as to be able to move while maintaining. The vacuum valve 17 has an upper end plate 36 and a lower end plate 31 at both ends of the insulated container, and the lower end plate 31 is fixed and supported by the insulator 39 via the high conductor 37. It is connected to the terminal 40 of the side. The current collector 45, which is always electrically connected to the movable contactor 12, is supported by the upper end plate 36, and the current collector 38 is supported by the lower end plate 31.

A movable main contactor 20 electrically connected to the current collector 38 is always provided, and the movable main contactor 20 can be detached from the fixed main contactor 16 provided in the high conductor 43. It is arranged. In addition, the movable main contactor 20 is connected to a manipulator not shown via the insulating rod 30. The first opening / closing part 1 shown in FIG. 1 is comprised by the vacuum valve 17 etc., and the 2nd opening-and-closing part 2 is comprised by the fixed contactor 11 and the movable contactor 12 etc., and the fixed main contact part ( 16) and the 3rd opening-and-closing part 3 are comprised by the movable main contactor 20 etc.

The vacuum valve 17 which comprises the 1st opening / closing part 1 shown in FIG. 9 has a pair of openable fixed electrode 18 and movable electrode 19, and it operates while maintaining a vacuum by the bellows 22. As shown in FIG. It is a structure which allows the opening operation | movement of the electrode 19, and is used as a vacuum circuit breaker. The holder 23 connected to the movable electrode 19 is led from the lower end plate 31. The first delay mechanism 26 is connected to the holder 23, and the first delay mechanism 26 is operated by an engaging portion 25 formed at an opposite portion of the insulating rod 30. It is configured to start. This 1st delay mechanism is the same structure as the above-mentioned embodiment shown in FIG.

One end of the lever 27 is connected to the lower end of the insulating rod 21 connected to the movable contact 12. The other end of the lever 27 is connected to the second retardation mechanism 51, which is a connecting portion having a margin formed at one end of the lever 29 via a link 28, and the other end of the lever 29 is connected to a rod ( 30). Therefore, when the rod 30 is driven downward by the manipulator, the movable main contactor 20 opens from the fixed main contactor 16, and the third opening and closing part 3 opens, and then the first delay mechanism 26. The first opening / closing part 1, which is the vacuum valve 17, is opened through the first and then the cylinder 14 and the movable contactor 12 are driven through the second delay mechanism 29 or the insulating rod 21 to move the movable contactor. The second opening and closing part 2 is opened by opening 12 from the fixed contact 11.

The high-voltage large-capacity circuit breaker having such a configuration can be operated in the same manner as in the above-described embodiment, and the fixed main contactor 16 and the movable main contactor 20 are used while using a vacuum interruption section that is weak against the impulse withstand voltage such as current carrying performance and multiple lightning strikes. By the third opening and closing portion (3) by the majority of the rated current flows to prevent the heat generation in the vacuum cut-off portion can increase the rated current. In addition, since the second opening / closing portion 2 is formed of the fixed contactor 11 and the movable contactor 12 to be opened in the insulating gas, the insulating gas may be used here, and the opening distance is increased compared to the vacuum interrupter to increase the impulse withstand voltage. It can increase.

It is a schematic front view which shows the specific structural example of the high voltage high capacity circuit breaker by other embodiment of this invention.

One end of the levers 46 and 50 is connected to the insulating rod 48 connected to the manipulator, not shown, via the links 47 and 49, respectively. One end of the rod 30 is connected to the other end of the lever 46, and the rod 30 is connected to the movable main contactor 20 which is in constant contact with the current collector 38. The fixed main contactor 16 facing the movable main contactor 20 is fixed to one terminal which is integrally connected to the upper end plate 36 of the vacuum valve 17. The vacuum valve 17 has an upper end plate 36 and a lower end plate 31 fixed to both ends of the insulating container, and is also used as a mechanical structure, and the current collector 38 is provided on the lower end plate 31. The configuration of the vacuum valve 17 is the same as in the above-described embodiment, and the holder 23 holding the movable electrode 19 can be opened and closed while maintaining the vacuum by the bellows. The first retardation mechanism 26 is connected to the end of the holder 23, and the first retardation mechanism 26 is operated by the engaging portion 25 formed on the opposite surface of the rod 30. It starts. The operating characteristics of the third opening / closing part 3 composed of the fixed main contactor 16, the movable main contactor 20, and the like, and the first opening / closing part 1 composed of the vacuum valve 17 or the like are the same as those of the above-described embodiment.

On the other hand, at the other end of the lever 50, a second delay mechanism portion 51 is formed, and the movable contact 12 of the second opening / closing portion 2 is connected via the second delay mechanism portion 51. The fixed contact 11 facing the movable contact 12 is provided in the other terminal 10. The other terminal 10 and the one terminal 36 described above are supported in an electrically insulated state from the hermetically sealed container by an insulator (not shown).

The interruption operation is performed by driving the insulating rod 48 to the right by an operator (not shown). The lever 46 rotates counterclockwise to open the movable main contactor 20 from the fixed main contactor 16 via the rod 30. At this time, the lever 50 is also rotated in the clockwise direction, the operation force is not yet transmitted to the movable contact 12 by the second delay mechanism (51). When the dielectric breakdown voltage between the movable main contactor 20 and the fixed main contactor 16 becomes high, the engaging portion 25 of the rod 30 activates the first retardation mechanism 26 and is shown in FIGS. 6 to 8. As described above, the vacuum interrupter is opened. When the movable electrode 19 is opened for a predetermined distance from the fixed electrode 19, for example, 0.6 cycles have elapsed, the idle movement by the second retardation mechanism 29 is stopped and the movable contactor 12 is driven upward to fix the fixed contactor. Open from (11). In this state, the gas opening / closing part including the fixed contactor 11 and the movable contactor 12 has a sufficient opening distance and can withstand more severe multiple lightning impulses by the insulating ability of the insulating gas.

As can be seen from this description, the high-voltage large-capacity circuit breaker according to the present invention is not limited to the configuration in which the three open / close parts 1 to 3 are opened and closed in the same direction, but may use a basic configuration such as a conventional two-point breaker. It can also be configured using other configurations.

It is a schematic block diagram which shows the high voltage large capacity circuit breaker by further another embodiment of this invention.

The first opening / closing portions 1a and 1b of two points connected in series are constituted by a vacuum blocking portion, juxtaposed in the sealed container 44 to form a main circuit in a substantially U shape, and the first opening and closing portions 1a and 1b are formed. The third opening / closing part 3 which forms the main flow path by the type which bridges the upper part of is connected. Moreover, the 2nd opening-and-closing part 2 comprised from the gas opening-closing part is connected in series only to the upper part of one 1st opening-and-closing part 1b. Each opening-closing part 1a-3 is made to open and close by the operating device 51 arrange | positioned under the airtight container 44, respectively, and each opening timing is the same as that of the above-mentioned embodiment. First, the third opening and closing part 3 is opened, and then the first opening and closing parts 1a and 1b of two points are opened via the first delay mechanism, and after the predetermined time, the second opening and closing part 2 is opened via the second delay mechanism. Become dog

It is a schematic block diagram which shows the high voltage large capacity circuit breaker by further another embodiment of this invention.

In this embodiment, the first opening and closing portion 1a constituted by the vacuum cutoff portion, the second opening and closing portion 2 constituted by the gas opening and closing portion electrically connected in series with the first opening and closing portion 1a, and the electrical opening and closing portion 1a are electrically parallel. And the current flows through the first opening / closing portion 1b and the first opening / closing portion 1a and the first opening / closing portion 1b, which are constituted by the vacuum interrupting portion of the first opening / closing portion 1a and the vacuum breaking portion of the same rated product. In order to adjust the ratio, high-voltage large-capacity circuit breakers are constituted by the impedance adjusting reactors 52a and 52b respectively connected. Here, the 1st opening-closing part 1a, 1b uses the 3rd opening-and-closing part 3 shown in FIG. 1, and the interruption | blocking operation simultaneously opens the 1st opening-and-closing part 1a, 1b, and is the same as that of the above-mentioned embodiment after that. The second opening and closing part 2 is opened at the timing.

According to the high-voltage large-capacity circuit breaker having such a configuration, the main open circuits are formed by the first opening / closing portions 1a and 1b which are connected in parallel with the vacuum interrupter, and the respective classification ratios are adjusted by the impedance adjusting reactors 52a and 52b. Therefore, even when using a vacuum interruption portion that is weak against impulse withstand pressure such as multiple lightning strikes, the impulse withstand pressure can be increased by increasing the internal pressure by increasing the opening distance as compared with the vacuum interruption portion by the second opening / closing portion 2 opening in the insulating gas. It has the same effect as that of one embodiment, and because each of the vacuum interrupting portions flows, for example, 1/2 of the rated current, it is possible to prevent heat generation at the vacuum interrupting portion and increase the rated current.

5, 9 and 10 are combined to form a configuration of the first opening and closing portion 1, the second opening and closing portion 2 and the third opening and closing portion 3 shown in FIGS. 5 and 9. When a pair of upper and lower parts are formed with the mechanism part represented by (29) as a center, and the mechanism parts located at the center part are collectively operated by an insulating rod as shown in Fig. 10, a two-point configuration in a normal circuit breaker can be realized. A divided voltage capacitor is connected in parallel to each of the first open / close parts 1 having a two-fold configuration, and the divided voltages are equalized. However, each of the divided voltage capacitors has an outer circumference of an electrode of the vacuum cutoff part that constitutes each of the first open / close parts 1. Since the intermediate shield is arranged in the portion, the intermediate shield may be used to provide an intermediate potential.

The high voltage large capacity circuit breaker by this invention is applicable also to the high voltage large capacity circuit breaker of the structure of that excepting above-mentioned embodiment. For example, although the 3rd switch part 3 is provided in parallel with the 1st switch part 1, it can also be set as the high voltage large capacity circuit breaker which abbreviate | omitted this 3 switch part 3 according to a rated current.

According to the high-voltage large-capacity circuit breaker of the present invention, since the second opening and closing part is opened after withstanding the transient vibration voltage applied between the poles after the current interruption, the opening distance between the contacts of the second opening and closing part is compared with that of the vacuum interrupting part. It can be made large enough to obtain high dielectric breakdown voltage, and it is possible to maintain good insulation against multiple lightning impulses and the like, thereby enabling high voltage and large capacity with a simple configuration.

Claims (10)

In the high-voltage large-capacity circuit breaker having a first opening and closing portion using a vacuum interrupter and a second opening and closing portion electrically connected in series with the first opening and closing portion, A high voltage and high capacity configured to open the first opening and closing part to withstand the transient vibration voltage after the current interruption in the first opening and closing part, and then open the second opening and closing part to withstand the impulse voltage in the second opening and closing part. breaker. In the high-voltage large-capacity circuit breaker having a first opening and closing portion using a vacuum interrupter, and a second opening and closing portion electrically connected in series with the first opening and closing portion, Opening the first opening / closing part based on a trip signal to withstand the transient vibration voltage after the current is cut off in the first opening / closing part, and then opening the second opening / closing part based on the trip signal to cut off the impulse voltage in the second opening / closing part. High voltage large capacity circuit breaker, configured to complete. In the high-voltage large-capacity circuit breaker having a first opening and closing portion using a vacuum interrupter and a second opening and closing portion electrically connected in series with the first opening and closing portion, The first opening / closing part is opened based on a trip signal, and the second opening / closing part is opened based on the trip signal after the maximum arc time after the distance between the electrodes of the first opening / closing part becomes a predetermined opening distance. High voltage large capacity circuit breaker. In the high-voltage large-capacity circuit breaker having a first opening and closing portion using a vacuum interrupter and a second opening and closing portion electrically connected in series with the first opening and closing portion, And the first opening / closing part is opened based on a trip signal, and thereafter, the second opening / closing part is opened within a rated breaking time based on the trip signal. In the high-voltage large-capacity circuit breaker having a first opening and closing portion using a vacuum interrupter and a second opening and closing portion electrically connected in series with the first opening and closing portion, The high-voltage high-capacity circuit breaker characterized by the above-mentioned opening and closing of the first opening and closing part, so that the second opening and closing part is completely opened within 0.3 seconds. In the high-voltage large-capacity circuit breaker having a first opening and closing portion using a vacuum interrupter and a second opening and closing portion electrically connected in series with the first opening and closing portion, And a high voltage capacity circuit breaker configured to be in a fully open state from 8.3 ms to 10 ms after opening the first switch. The method according to any one of claims 1 to 6, And a third opening and closing portion electrically connected in parallel to the first opening and closing portion to form a main communication path, and the first opening and closing portion is opened after opening the third opening and closing portion. A high-voltage large-capacity circuit breaker having a first opening and closing portion using a vacuum interrupter, a second opening and closing portion electrically connected in series to the first opening and closing portion, and a third opening and closing portion at least electrically connected in parallel to the first opening and closing portion to form a main communication path. To A manipulator for blocking operation based on a trip signal is provided, and the third opening / closing part is connected so as to be opened by the manipulator so as to open the third opening / closing part between the first opening part and the manipulator, and then transfer the operating force to be opened. And a second delay mechanism for transmitting a control force for opening the second opening / closing part after opening of the first opening / closing part between the second opening / closing part and the manipulator. . Following any one of claims 1 to 6 or 8, The second opening and closing portion is a high-voltage high-capacity circuit breaker, characterized in that it comprises a fixed contactor and a movable contactor that can be opened and closed in a sealed container filled with insulating gas. The method of claim 9, And said insulating gas is an insulating gas having a smaller warming coefficient than SF6 gas.

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